// SPDX-License-Identifier: GPL-2.0-or-later /* cx231xx_avcore.c - driver for Conexant Cx23100/101/102 USB video capture devices Copyright (C) 2008 This program contains the specific code to control the avdecoder chip and other related usb control functions for cx231xx based chipset. */ #include "cx231xx.h" #include #include #include #include #include #include #include #include #include #include #include #include "cx231xx-dif.h" #define TUNER_MODE_FM_RADIO 0 /****************************************************************************** -: BLOCK ARRANGEMENT :- I2S block ----------------------| [I2S audio] | | Analog Front End --> Direct IF -|-> Cx25840 --> Audio [video & audio] | [Audio] | |-> Cx25840 --> Video [Video] *******************************************************************************/ /****************************************************************************** * VERVE REGISTER * * * ******************************************************************************/ static int verve_write_byte(struct cx231xx *dev, u8 saddr, u8 data) { return cx231xx_write_i2c_data(dev, VERVE_I2C_ADDRESS, saddr, 1, data, 1); } static int verve_read_byte(struct cx231xx *dev, u8 saddr, u8 *data) { int status; u32 temp = 0; status = cx231xx_read_i2c_data(dev, VERVE_I2C_ADDRESS, saddr, 1, &temp, 1); *data = (u8) temp; return status; } void initGPIO(struct cx231xx *dev) { u32 _gpio_direction = 0; u32 value = 0; u8 val = 0; _gpio_direction = _gpio_direction & 0xFC0003FF; _gpio_direction = _gpio_direction | 0x03FDFC00; cx231xx_send_gpio_cmd(dev, _gpio_direction, (u8 *)&value, 4, 0, 0); verve_read_byte(dev, 0x07, &val); dev_dbg(dev->dev, "verve_read_byte address0x07=0x%x\n", val); verve_write_byte(dev, 0x07, 0xF4); verve_read_byte(dev, 0x07, &val); dev_dbg(dev->dev, "verve_read_byte address0x07=0x%x\n", val); cx231xx_capture_start(dev, 1, Vbi); cx231xx_mode_register(dev, EP_MODE_SET, 0x0500FE00); cx231xx_mode_register(dev, GBULK_BIT_EN, 0xFFFDFFFF); } void uninitGPIO(struct cx231xx *dev) { u8 value[4] = { 0, 0, 0, 0 }; cx231xx_capture_start(dev, 0, Vbi); verve_write_byte(dev, 0x07, 0x14); cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, 0x68, value, 4); } /****************************************************************************** * A F E - B L O C K C O N T R O L functions * * [ANALOG FRONT END] * ******************************************************************************/ static int afe_write_byte(struct cx231xx *dev, u16 saddr, u8 data) { return cx231xx_write_i2c_data(dev, AFE_DEVICE_ADDRESS, saddr, 2, data, 1); } static int afe_read_byte(struct cx231xx *dev, u16 saddr, u8 *data) { int status; u32 temp = 0; status = cx231xx_read_i2c_data(dev, AFE_DEVICE_ADDRESS, saddr, 2, &temp, 1); *data = (u8) temp; return status; } int cx231xx_afe_init_super_block(struct cx231xx *dev, u32 ref_count) { int status = 0; u8 temp = 0; u8 afe_power_status = 0; int i = 0; /* super block initialize */ temp = (u8) (ref_count & 0xff); status = afe_write_byte(dev, SUP_BLK_TUNE2, temp); if (status < 0) return status; status = afe_read_byte(dev, SUP_BLK_TUNE2, &afe_power_status); if (status < 0) return status; temp = (u8) ((ref_count & 0x300) >> 8); temp |= 0x40; status = afe_write_byte(dev, SUP_BLK_TUNE1, temp); if (status < 0) return status; status = afe_write_byte(dev, SUP_BLK_PLL2, 0x0f); if (status < 0) return status; /* enable pll */ while (afe_power_status != 0x18) { status = afe_write_byte(dev, SUP_BLK_PWRDN, 0x18); if (status < 0) { dev_dbg(dev->dev, "%s: Init Super Block failed in send cmd\n", __func__); break; } status = afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); afe_power_status &= 0xff; if (status < 0) { dev_dbg(dev->dev, "%s: Init Super Block failed in receive cmd\n", __func__); break; } i++; if (i == 10) { dev_dbg(dev->dev, "%s: Init Super Block force break in loop !!!!\n", __func__); status = -1; break; } } if (status < 0) return status; /* start tuning filter */ status = afe_write_byte(dev, SUP_BLK_TUNE3, 0x40); if (status < 0) return status; msleep(5); /* exit tuning */ status = afe_write_byte(dev, SUP_BLK_TUNE3, 0x00); return status; } int cx231xx_afe_init_channels(struct cx231xx *dev) { int status = 0; /* power up all 3 channels, clear pd_buffer */ status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x00); status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x00); status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x00); /* Enable quantizer calibration */ status = afe_write_byte(dev, ADC_COM_QUANT, 0x02); /* channel initialize, force modulator (fb) reset */ status = afe_write_byte(dev, ADC_FB_FRCRST_CH1, 0x17); status = afe_write_byte(dev, ADC_FB_FRCRST_CH2, 0x17); status = afe_write_byte(dev, ADC_FB_FRCRST_CH3, 0x17); /* start quantilizer calibration */ status = afe_write_byte(dev, ADC_CAL_ATEST_CH1, 0x10); status = afe_write_byte(dev, ADC_CAL_ATEST_CH2, 0x10); status = afe_write_byte(dev, ADC_CAL_ATEST_CH3, 0x10); msleep(5); /* exit modulator (fb) reset */ status = afe_write_byte(dev, ADC_FB_FRCRST_CH1, 0x07); status = afe_write_byte(dev, ADC_FB_FRCRST_CH2, 0x07); status = afe_write_byte(dev, ADC_FB_FRCRST_CH3, 0x07); /* enable the pre_clamp in each channel for single-ended input */ status = afe_write_byte(dev, ADC_NTF_PRECLMP_EN_CH1, 0xf0); status = afe_write_byte(dev, ADC_NTF_PRECLMP_EN_CH2, 0xf0); status = afe_write_byte(dev, ADC_NTF_PRECLMP_EN_CH3, 0xf0); /* use diode instead of resistor, so set term_en to 0, res_en to 0 */ status = cx231xx_reg_mask_write(dev, AFE_DEVICE_ADDRESS, 8, ADC_QGAIN_RES_TRM_CH1, 3, 7, 0x00); status = cx231xx_reg_mask_write(dev, AFE_DEVICE_ADDRESS, 8, ADC_QGAIN_RES_TRM_CH2, 3, 7, 0x00); status = cx231xx_reg_mask_write(dev, AFE_DEVICE_ADDRESS, 8, ADC_QGAIN_RES_TRM_CH3, 3, 7, 0x00); /* dynamic element matching off */ status = afe_write_byte(dev, ADC_DCSERVO_DEM_CH1, 0x03); status = afe_write_byte(dev, ADC_DCSERVO_DEM_CH2, 0x03); status = afe_write_byte(dev, ADC_DCSERVO_DEM_CH3, 0x03); return status; } int cx231xx_afe_setup_AFE_for_baseband(struct cx231xx *dev) { u8 c_value = 0; int status = 0; status = afe_read_byte(dev, ADC_PWRDN_CLAMP_CH2, &c_value); c_value &= (~(0x50)); status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, c_value); return status; } /* The Analog Front End in Cx231xx has 3 channels. These channels are used to share between different inputs like tuner, s-video and composite inputs. channel 1 ----- pin 1 to pin4(in reg is 1-4) channel 2 ----- pin 5 to pin8(in reg is 5-8) channel 3 ----- pin 9 to pin 12(in reg is 9-11) */ int cx231xx_afe_set_input_mux(struct cx231xx *dev, u32 input_mux) { u8 ch1_setting = (u8) input_mux; u8 ch2_setting = (u8) (input_mux >> 8); u8 ch3_setting = (u8) (input_mux >> 16); int status = 0; u8 value = 0; if (ch1_setting != 0) { status = afe_read_byte(dev, ADC_INPUT_CH1, &value); value &= ~INPUT_SEL_MASK; value |= (ch1_setting - 1) << 4; value &= 0xff; status = afe_write_byte(dev, ADC_INPUT_CH1, value); } if (ch2_setting != 0) { status = afe_read_byte(dev, ADC_INPUT_CH2, &value); value &= ~INPUT_SEL_MASK; value |= (ch2_setting - 1) << 4; value &= 0xff; status = afe_write_byte(dev, ADC_INPUT_CH2, value); } /* For ch3_setting, the value to put in the register is 7 less than the input number */ if (ch3_setting != 0) { status = afe_read_byte(dev, ADC_INPUT_CH3, &value); value &= ~INPUT_SEL_MASK; value |= (ch3_setting - 1) << 4; value &= 0xff; status = afe_write_byte(dev, ADC_INPUT_CH3, value); } return status; } int cx231xx_afe_set_mode(struct cx231xx *dev, enum AFE_MODE mode) { int status = 0; /* * FIXME: We need to implement the AFE code for LOW IF and for HI IF. * Currently, only baseband works. */ switch (mode) { case AFE_MODE_LOW_IF: cx231xx_Setup_AFE_for_LowIF(dev); break; case AFE_MODE_BASEBAND: status = cx231xx_afe_setup_AFE_for_baseband(dev); break; case AFE_MODE_EU_HI_IF: /* SetupAFEforEuHiIF(); */ break; case AFE_MODE_US_HI_IF: /* SetupAFEforUsHiIF(); */ break; case AFE_MODE_JAPAN_HI_IF: /* SetupAFEforJapanHiIF(); */ break; } if ((mode != dev->afe_mode) && (dev->video_input == CX231XX_VMUX_TELEVISION)) status = cx231xx_afe_adjust_ref_count(dev, CX231XX_VMUX_TELEVISION); dev->afe_mode = mode; return status; } int cx231xx_afe_update_power_control(struct cx231xx *dev, enum AV_MODE avmode) { u8 afe_power_status = 0; int status = 0; switch (dev->model) { case CX231XX_BOARD_CNXT_CARRAERA: case CX231XX_BOARD_CNXT_RDE_250: case CX231XX_BOARD_CNXT_SHELBY: case CX231XX_BOARD_CNXT_RDU_250: case CX231XX_BOARD_CNXT_RDE_253S: case CX231XX_BOARD_CNXT_RDU_253S: case CX231XX_BOARD_CNXT_VIDEO_GRABBER: case CX231XX_BOARD_HAUPPAUGE_EXETER: case CX231XX_BOARD_HAUPPAUGE_930C_HD_1113xx: case CX231XX_BOARD_HAUPPAUGE_USBLIVE2: case CX231XX_BOARD_PV_PLAYTV_USB_HYBRID: case CX231XX_BOARD_HAUPPAUGE_USB2_FM_PAL: case CX231XX_BOARD_HAUPPAUGE_USB2_FM_NTSC: case CX231XX_BOARD_OTG102: if (avmode == POLARIS_AVMODE_ANALOGT_TV) { while (afe_power_status != (FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL)) { status = afe_write_byte(dev, SUP_BLK_PWRDN, FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL); status |= afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); if (status < 0) break; } status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x00); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x00); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x00); } else if (avmode == POLARIS_AVMODE_DIGITAL) { status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x70); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x70); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x70); status |= afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); afe_power_status |= FLD_PWRDN_PD_BANDGAP | FLD_PWRDN_PD_BIAS | FLD_PWRDN_PD_TUNECK; status |= afe_write_byte(dev, SUP_BLK_PWRDN, afe_power_status); } else if (avmode == POLARIS_AVMODE_ENXTERNAL_AV) { while (afe_power_status != (FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL)) { status = afe_write_byte(dev, SUP_BLK_PWRDN, FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL); status |= afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); if (status < 0) break; } status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x00); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x00); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x00); } else { dev_dbg(dev->dev, "Invalid AV mode input\n"); status = -1; } break; default: if (avmode == POLARIS_AVMODE_ANALOGT_TV) { while (afe_power_status != (FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL)) { status = afe_write_byte(dev, SUP_BLK_PWRDN, FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL); status |= afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); if (status < 0) break; } status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x40); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x40); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x00); } else if (avmode == POLARIS_AVMODE_DIGITAL) { status = afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x70); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x70); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x70); status |= afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); afe_power_status |= FLD_PWRDN_PD_BANDGAP | FLD_PWRDN_PD_BIAS | FLD_PWRDN_PD_TUNECK; status |= afe_write_byte(dev, SUP_BLK_PWRDN, afe_power_status); } else if (avmode == POLARIS_AVMODE_ENXTERNAL_AV) { while (afe_power_status != (FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL)) { status = afe_write_byte(dev, SUP_BLK_PWRDN, FLD_PWRDN_TUNING_BIAS | FLD_PWRDN_ENABLE_PLL); status |= afe_read_byte(dev, SUP_BLK_PWRDN, &afe_power_status); if (status < 0) break; } status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH1, 0x00); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH2, 0x00); status |= afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, 0x40); } else { dev_dbg(dev->dev, "Invalid AV mode input\n"); status = -1; } } /* switch */ return status; } int cx231xx_afe_adjust_ref_count(struct cx231xx *dev, u32 video_input) { u8 input_mode = 0; u8 ntf_mode = 0; int status = 0; dev->video_input = video_input; if (video_input == CX231XX_VMUX_TELEVISION) { status = afe_read_byte(dev, ADC_INPUT_CH3, &input_mode); status = afe_read_byte(dev, ADC_NTF_PRECLMP_EN_CH3, &ntf_mode); } else { status = afe_read_byte(dev, ADC_INPUT_CH1, &input_mode); status = afe_read_byte(dev, ADC_NTF_PRECLMP_EN_CH1, &ntf_mode); } input_mode = (ntf_mode & 0x3) | ((input_mode & 0x6) << 1); switch (input_mode) { case SINGLE_ENDED: dev->afe_ref_count = 0x23C; break; case LOW_IF: dev->afe_ref_count = 0x24C; break; case EU_IF: dev->afe_ref_count = 0x258; break; case US_IF: dev->afe_ref_count = 0x260; break; default: break; } status = cx231xx_afe_init_super_block(dev, dev->afe_ref_count); return status; } /****************************************************************************** * V I D E O / A U D I O D E C O D E R C O N T R O L functions * ******************************************************************************/ static int vid_blk_write_byte(struct cx231xx *dev, u16 saddr, u8 data) { return cx231xx_write_i2c_data(dev, VID_BLK_I2C_ADDRESS, saddr, 2, data, 1); } static int vid_blk_read_byte(struct cx231xx *dev, u16 saddr, u8 *data) { int status; u32 temp = 0; status = cx231xx_read_i2c_data(dev, VID_BLK_I2C_ADDRESS, saddr, 2, &temp, 1); *data = (u8) temp; return status; } static int vid_blk_write_word(struct cx231xx *dev, u16 saddr, u32 data) { return cx231xx_write_i2c_data(dev, VID_BLK_I2C_ADDRESS, saddr, 2, data, 4); } static int vid_blk_read_word(struct cx231xx *dev, u16 saddr, u32 *data) { return cx231xx_read_i2c_data(dev, VID_BLK_I2C_ADDRESS, saddr, 2, data, 4); } int cx231xx_check_fw(struct cx231xx *dev) { u8 temp = 0; int status = 0; status = vid_blk_read_byte(dev, DL_CTL_ADDRESS_LOW, &temp); if (status < 0) return status; else return temp; } int cx231xx_set_video_input_mux(struct cx231xx *dev, u8 input) { int status = 0; switch (INPUT(input)->type) { case CX231XX_VMUX_COMPOSITE1: case CX231XX_VMUX_SVIDEO: if ((dev->current_pcb_config.type == USB_BUS_POWER) && (dev->power_mode != POLARIS_AVMODE_ENXTERNAL_AV)) { /* External AV */ status = cx231xx_set_power_mode(dev, POLARIS_AVMODE_ENXTERNAL_AV); if (status < 0) { dev_err(dev->dev, "%s: Failed to set Power - errCode [%d]!\n", __func__, status); return status; } } status = cx231xx_set_decoder_video_input(dev, INPUT(input)->type, INPUT(input)->vmux); break; case CX231XX_VMUX_TELEVISION: case CX231XX_VMUX_CABLE: if ((dev->current_pcb_config.type == USB_BUS_POWER) && (dev->power_mode != POLARIS_AVMODE_ANALOGT_TV)) { /* Tuner */ status = cx231xx_set_power_mode(dev, POLARIS_AVMODE_ANALOGT_TV); if (status < 0) { dev_err(dev->dev, "%s: Failed to set Power - errCode [%d]!\n", __func__, status); return status; } } if (dev->tuner_type == TUNER_NXP_TDA18271) status = cx231xx_set_decoder_video_input(dev, CX231XX_VMUX_TELEVISION, INPUT(input)->vmux); else status = cx231xx_set_decoder_video_input(dev, CX231XX_VMUX_COMPOSITE1, INPUT(input)->vmux); break; default: dev_err(dev->dev, "%s: Unknown Input %d !\n", __func__, INPUT(input)->type); break; } /* save the selection */ dev->video_input = input; return status; } int cx231xx_set_decoder_video_input(struct cx231xx *dev, u8 pin_type, u8 input) { int status = 0; u32 value = 0; if (pin_type != dev->video_input) { status = cx231xx_afe_adjust_ref_count(dev, pin_type); if (status < 0) { dev_err(dev->dev, "%s: adjust_ref_count :Failed to set AFE input mux - errCode [%d]!\n", __func__, status); return status; } } /* call afe block to set video inputs */ status = cx231xx_afe_set_input_mux(dev, input); if (status < 0) { dev_err(dev->dev, "%s: set_input_mux :Failed to set AFE input mux - errCode [%d]!\n", __func__, status); return status; } switch (pin_type) { case CX231XX_VMUX_COMPOSITE1: status = vid_blk_read_word(dev, AFE_CTRL, &value); value |= (0 << 13) | (1 << 4); value &= ~(1 << 5); /* set [24:23] [22:15] to 0 */ value &= (~(0x1ff8000)); /* set FUNC_MODE[24:23] = 2 IF_MOD[22:15] = 0 */ value |= 0x1000000; status = vid_blk_write_word(dev, AFE_CTRL, value); status = vid_blk_read_word(dev, OUT_CTRL1, &value); value |= (1 << 7); status = vid_blk_write_word(dev, OUT_CTRL1, value); /* Set output mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, OUT_CTRL1, FLD_OUT_MODE, dev->board.output_mode); /* Tell DIF object to go to baseband mode */ status = cx231xx_dif_set_standard(dev, DIF_USE_BASEBAND); if (status < 0) { dev_err(dev->dev, "%s: cx231xx_dif set to By pass mode- errCode [%d]!\n", __func__, status); return status; } /* Read the DFE_CTRL1 register */ status = vid_blk_read_word(dev, DFE_CTRL1, &value); /* enable the VBI_GATE_EN */ value |= FLD_VBI_GATE_EN; /* Enable the auto-VGA enable */ value |= FLD_VGA_AUTO_EN; /* Write it back */ status = vid_blk_write_word(dev, DFE_CTRL1, value); /* Disable auto config of registers */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_ACFG_DIS, cx231xx_set_field(FLD_ACFG_DIS, 1)); /* Set CVBS input mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_INPUT_MODE, cx231xx_set_field(FLD_INPUT_MODE, INPUT_MODE_CVBS_0)); break; case CX231XX_VMUX_SVIDEO: /* Disable the use of DIF */ status = vid_blk_read_word(dev, AFE_CTRL, &value); /* set [24:23] [22:15] to 0 */ value &= (~(0x1ff8000)); /* set FUNC_MODE[24:23] = 2 IF_MOD[22:15] = 0 DCR_BYP_CH2[4:4] = 1; */ value |= 0x1000010; status = vid_blk_write_word(dev, AFE_CTRL, value); /* Tell DIF object to go to baseband mode */ status = cx231xx_dif_set_standard(dev, DIF_USE_BASEBAND); if (status < 0) { dev_err(dev->dev, "%s: cx231xx_dif set to By pass mode- errCode [%d]!\n", __func__, status); return status; } /* Read the DFE_CTRL1 register */ status = vid_blk_read_word(dev, DFE_CTRL1, &value); /* enable the VBI_GATE_EN */ value |= FLD_VBI_GATE_EN; /* Enable the auto-VGA enable */ value |= FLD_VGA_AUTO_EN; /* Write it back */ status = vid_blk_write_word(dev, DFE_CTRL1, value); /* Disable auto config of registers */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_ACFG_DIS, cx231xx_set_field(FLD_ACFG_DIS, 1)); /* Set YC input mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_INPUT_MODE, cx231xx_set_field(FLD_INPUT_MODE, INPUT_MODE_YC_1)); /* Chroma to ADC2 */ status = vid_blk_read_word(dev, AFE_CTRL, &value); value |= FLD_CHROMA_IN_SEL; /* set the chroma in select */ /* Clear VGA_SEL_CH2 and VGA_SEL_CH3 (bits 7 and 8) This sets them to use video rather than audio. Only one of the two will be in use. */ value &= ~(FLD_VGA_SEL_CH2 | FLD_VGA_SEL_CH3); status = vid_blk_write_word(dev, AFE_CTRL, value); status = cx231xx_afe_set_mode(dev, AFE_MODE_BASEBAND); break; case CX231XX_VMUX_TELEVISION: case CX231XX_VMUX_CABLE: default: /* TODO: Test if this is also needed for xc2028/xc3028 */ if (dev->board.tuner_type == TUNER_XC5000) { /* Disable the use of DIF */ status = vid_blk_read_word(dev, AFE_CTRL, &value); value |= (0 << 13) | (1 << 4); value &= ~(1 << 5); /* set [24:23] [22:15] to 0 */ value &= (~(0x1FF8000)); /* set FUNC_MODE[24:23] = 2 IF_MOD[22:15] = 0 */ value |= 0x1000000; status = vid_blk_write_word(dev, AFE_CTRL, value); status = vid_blk_read_word(dev, OUT_CTRL1, &value); value |= (1 << 7); status = vid_blk_write_word(dev, OUT_CTRL1, value); /* Set output mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, OUT_CTRL1, FLD_OUT_MODE, dev->board.output_mode); /* Tell DIF object to go to baseband mode */ status = cx231xx_dif_set_standard(dev, DIF_USE_BASEBAND); if (status < 0) { dev_err(dev->dev, "%s: cx231xx_dif set to By pass mode- errCode [%d]!\n", __func__, status); return status; } /* Read the DFE_CTRL1 register */ status = vid_blk_read_word(dev, DFE_CTRL1, &value); /* enable the VBI_GATE_EN */ value |= FLD_VBI_GATE_EN; /* Enable the auto-VGA enable */ value |= FLD_VGA_AUTO_EN; /* Write it back */ status = vid_blk_write_word(dev, DFE_CTRL1, value); /* Disable auto config of registers */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_ACFG_DIS, cx231xx_set_field(FLD_ACFG_DIS, 1)); /* Set CVBS input mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_INPUT_MODE, cx231xx_set_field(FLD_INPUT_MODE, INPUT_MODE_CVBS_0)); } else { /* Enable the DIF for the tuner */ /* Reinitialize the DIF */ status = cx231xx_dif_set_standard(dev, dev->norm); if (status < 0) { dev_err(dev->dev, "%s: cx231xx_dif set to By pass mode- errCode [%d]!\n", __func__, status); return status; } /* Make sure bypass is cleared */ status = vid_blk_read_word(dev, DIF_MISC_CTRL, &value); /* Clear the bypass bit */ value &= ~FLD_DIF_DIF_BYPASS; /* Enable the use of the DIF block */ status = vid_blk_write_word(dev, DIF_MISC_CTRL, value); /* Read the DFE_CTRL1 register */ status = vid_blk_read_word(dev, DFE_CTRL1, &value); /* Disable the VBI_GATE_EN */ value &= ~FLD_VBI_GATE_EN; /* Enable the auto-VGA enable, AGC, and set the skip count to 2 */ value |= FLD_VGA_AUTO_EN | FLD_AGC_AUTO_EN | 0x00200000; /* Write it back */ status = vid_blk_write_word(dev, DFE_CTRL1, value); /* Wait until AGC locks up */ msleep(1); /* Disable the auto-VGA enable AGC */ value &= ~(FLD_VGA_AUTO_EN); /* Write it back */ status = vid_blk_write_word(dev, DFE_CTRL1, value); /* Enable Polaris B0 AGC output */ status = vid_blk_read_word(dev, PIN_CTRL, &value); value |= (FLD_OEF_AGC_RF) | (FLD_OEF_AGC_IFVGA) | (FLD_OEF_AGC_IF); status = vid_blk_write_word(dev, PIN_CTRL, value); /* Set output mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, OUT_CTRL1, FLD_OUT_MODE, dev->board.output_mode); /* Disable auto config of registers */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_ACFG_DIS, cx231xx_set_field(FLD_ACFG_DIS, 1)); /* Set CVBS input mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, MODE_CTRL, FLD_INPUT_MODE, cx231xx_set_field(FLD_INPUT_MODE, INPUT_MODE_CVBS_0)); /* Set some bits in AFE_CTRL so that channel 2 or 3 * is ready to receive audio */ /* Clear clamp for channels 2 and 3 (bit 16-17) */ /* Clear droop comp (bit 19-20) */ /* Set VGA_SEL (for audio control) (bit 7-8) */ status = vid_blk_read_word(dev, AFE_CTRL, &value); /*Set Func mode:01-DIF 10-baseband 11-YUV*/ value &= (~(FLD_FUNC_MODE)); value |= 0x800000; value |= FLD_VGA_SEL_CH3 | FLD_VGA_SEL_CH2; status = vid_blk_write_word(dev, AFE_CTRL, value); if (dev->tuner_type == TUNER_NXP_TDA18271) { status = vid_blk_read_word(dev, PIN_CTRL, &value); status = vid_blk_write_word(dev, PIN_CTRL, (value & 0xFFFFFFEF)); } break; } break; } /* Set raw VBI mode */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, OUT_CTRL1, FLD_VBIHACTRAW_EN, cx231xx_set_field(FLD_VBIHACTRAW_EN, 1)); status = vid_blk_read_word(dev, OUT_CTRL1, &value); if (value & 0x02) { value |= (1 << 19); status = vid_blk_write_word(dev, OUT_CTRL1, value); } return status; } void cx231xx_enable656(struct cx231xx *dev) { u8 temp = 0; /*enable TS1 data[0:7] as output to export 656*/ vid_blk_write_byte(dev, TS1_PIN_CTL0, 0xFF); /*enable TS1 clock as output to export 656*/ vid_blk_read_byte(dev, TS1_PIN_CTL1, &temp); temp = temp|0x04; vid_blk_write_byte(dev, TS1_PIN_CTL1, temp); } EXPORT_SYMBOL_GPL(cx231xx_enable656); void cx231xx_disable656(struct cx231xx *dev) { u8 temp = 0; vid_blk_write_byte(dev, TS1_PIN_CTL0, 0x00); vid_blk_read_byte(dev, TS1_PIN_CTL1, &temp); temp = temp&0xFB; vid_blk_write_byte(dev, TS1_PIN_CTL1, temp); } EXPORT_SYMBOL_GPL(cx231xx_disable656); /* * Handle any video-mode specific overrides that are different * on a per video standards basis after touching the MODE_CTRL * register which resets many values for autodetect */ int cx231xx_do_mode_ctrl_overrides(struct cx231xx *dev) { int status = 0; dev_dbg(dev->dev, "%s: 0x%x\n", __func__, (unsigned int)dev->norm); /* Change the DFE_CTRL3 bp_percent to fix flagging */ status = vid_blk_write_word(dev, DFE_CTRL3, 0xCD3F0280); if (dev->norm & (V4L2_STD_NTSC | V4L2_STD_PAL_M)) { dev_dbg(dev->dev, "%s: NTSC\n", __func__); /* Move the close caption lines out of active video, adjust the active video start point */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_VBLANK_CNT, 0x18); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_VACTIVE_CNT, 0x1E7000); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_V656BLANK_CNT, 0x1C000000); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, HORIZ_TIM_CTRL, FLD_HBLANK_CNT, cx231xx_set_field (FLD_HBLANK_CNT, 0x79)); } else if (dev->norm & V4L2_STD_SECAM) { dev_dbg(dev->dev, "%s: SECAM\n", __func__); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_VBLANK_CNT, 0x20); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_VACTIVE_CNT, cx231xx_set_field (FLD_VACTIVE_CNT, 0x244)); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_V656BLANK_CNT, cx231xx_set_field (FLD_V656BLANK_CNT, 0x24)); /* Adjust the active video horizontal start point */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, HORIZ_TIM_CTRL, FLD_HBLANK_CNT, cx231xx_set_field (FLD_HBLANK_CNT, 0x85)); } else { dev_dbg(dev->dev, "%s: PAL\n", __func__); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_VBLANK_CNT, 0x20); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_VACTIVE_CNT, cx231xx_set_field (FLD_VACTIVE_CNT, 0x244)); status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, VERT_TIM_CTRL, FLD_V656BLANK_CNT, cx231xx_set_field (FLD_V656BLANK_CNT, 0x24)); /* Adjust the active video horizontal start point */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, HORIZ_TIM_CTRL, FLD_HBLANK_CNT, cx231xx_set_field (FLD_HBLANK_CNT, 0x85)); } return status; } int cx231xx_unmute_audio(struct cx231xx *dev) { return vid_blk_write_byte(dev, PATH1_VOL_CTL, 0x24); } EXPORT_SYMBOL_GPL(cx231xx_unmute_audio); static int stopAudioFirmware(struct cx231xx *dev) { return vid_blk_write_byte(dev, DL_CTL_CONTROL, 0x03); } static int restartAudioFirmware(struct cx231xx *dev) { return vid_blk_write_byte(dev, DL_CTL_CONTROL, 0x13); } int cx231xx_set_audio_input(struct cx231xx *dev, u8 input) { int status = 0; enum AUDIO_INPUT ainput = AUDIO_INPUT_LINE; switch (INPUT(input)->amux) { case CX231XX_AMUX_VIDEO: ainput = AUDIO_INPUT_TUNER_TV; break; case CX231XX_AMUX_LINE_IN: status = cx231xx_i2s_blk_set_audio_input(dev, input); ainput = AUDIO_INPUT_LINE; break; default: break; } status = cx231xx_set_audio_decoder_input(dev, ainput); return status; } int cx231xx_set_audio_decoder_input(struct cx231xx *dev, enum AUDIO_INPUT audio_input) { u32 dwval; int status; u8 gen_ctrl; u32 value = 0; /* Put it in soft reset */ status = vid_blk_read_byte(dev, GENERAL_CTL, &gen_ctrl); gen_ctrl |= 1; status = vid_blk_write_byte(dev, GENERAL_CTL, gen_ctrl); switch (audio_input) { case AUDIO_INPUT_LINE: /* setup AUD_IO control from Merlin paralle output */ value = cx231xx_set_field(FLD_AUD_CHAN1_SRC, AUD_CHAN_SRC_PARALLEL); status = vid_blk_write_word(dev, AUD_IO_CTRL, value); /* setup input to Merlin, SRC2 connect to AC97 bypass upsample-by-2, slave mode, sony mode, left justify adr 091c, dat 01000000 */ status = vid_blk_read_word(dev, AC97_CTL, &dwval); status = vid_blk_write_word(dev, AC97_CTL, (dwval | FLD_AC97_UP2X_BYPASS)); /* select the parallel1 and SRC3 */ status = vid_blk_write_word(dev, BAND_OUT_SEL, cx231xx_set_field(FLD_SRC3_IN_SEL, 0x0) | cx231xx_set_field(FLD_SRC3_CLK_SEL, 0x0) | cx231xx_set_field(FLD_PARALLEL1_SRC_SEL, 0x0)); /* unmute all, AC97 in, independence mode adr 08d0, data 0x00063073 */ status = vid_blk_write_word(dev, DL_CTL, 0x3000001); status = vid_blk_write_word(dev, PATH1_CTL1, 0x00063073); /* set AVC maximum threshold, adr 08d4, dat ffff0024 */ status = vid_blk_read_word(dev, PATH1_VOL_CTL, &dwval); status = vid_blk_write_word(dev, PATH1_VOL_CTL, (dwval | FLD_PATH1_AVC_THRESHOLD)); /* set SC maximum threshold, adr 08ec, dat ffffb3a3 */ status = vid_blk_read_word(dev, PATH1_SC_CTL, &dwval); status = vid_blk_write_word(dev, PATH1_SC_CTL, (dwval | FLD_PATH1_SC_THRESHOLD)); break; case AUDIO_INPUT_TUNER_TV: default: status = stopAudioFirmware(dev); /* Setup SRC sources and clocks */ status = vid_blk_write_word(dev, BAND_OUT_SEL, cx231xx_set_field(FLD_SRC6_IN_SEL, 0x00) | cx231xx_set_field(FLD_SRC6_CLK_SEL, 0x01) | cx231xx_set_field(FLD_SRC5_IN_SEL, 0x00) | cx231xx_set_field(FLD_SRC5_CLK_SEL, 0x02) | cx231xx_set_field(FLD_SRC4_IN_SEL, 0x02) | cx231xx_set_field(FLD_SRC4_CLK_SEL, 0x03) | cx231xx_set_field(FLD_SRC3_IN_SEL, 0x00) | cx231xx_set_field(FLD_SRC3_CLK_SEL, 0x00) | cx231xx_set_field(FLD_BASEBAND_BYPASS_CTL, 0x00) | cx231xx_set_field(FLD_AC97_SRC_SEL, 0x03) | cx231xx_set_field(FLD_I2S_SRC_SEL, 0x00) | cx231xx_set_field(FLD_PARALLEL2_SRC_SEL, 0x02) | cx231xx_set_field(FLD_PARALLEL1_SRC_SEL, 0x01)); /* Setup the AUD_IO control */ status = vid_blk_write_word(dev, AUD_IO_CTRL, cx231xx_set_field(FLD_I2S_PORT_DIR, 0x00) | cx231xx_set_field(FLD_I2S_OUT_SRC, 0x00) | cx231xx_set_field(FLD_AUD_CHAN3_SRC, 0x00) | cx231xx_set_field(FLD_AUD_CHAN2_SRC, 0x00) | cx231xx_set_field(FLD_AUD_CHAN1_SRC, 0x03)); status = vid_blk_write_word(dev, PATH1_CTL1, 0x1F063870); /* setAudioStandard(_audio_standard); */ status = vid_blk_write_word(dev, PATH1_CTL1, 0x00063870); status = restartAudioFirmware(dev); switch (dev->board.tuner_type) { case TUNER_XC5000: /* SIF passthrough at 28.6363 MHz sample rate */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, CHIP_CTRL, FLD_SIF_EN, cx231xx_set_field(FLD_SIF_EN, 1)); break; case TUNER_NXP_TDA18271: /* Normal mode: SIF passthrough at 14.32 MHz */ status = cx231xx_read_modify_write_i2c_dword(dev, VID_BLK_I2C_ADDRESS, CHIP_CTRL, FLD_SIF_EN, cx231xx_set_field(FLD_SIF_EN, 0)); break; default: /* This is just a casual suggestion to people adding new boards in case they use a tuner type we don't currently know about */ dev_info(dev->dev, "Unknown tuner type configuring SIF"); break; } break; case AUDIO_INPUT_TUNER_FM: /* use SIF for FM radio setupFM(); setAudioStandard(_audio_standard); */ break; case AUDIO_INPUT_MUTE: status = vid_blk_write_word(dev, PATH1_CTL1, 0x1F011012); break; } /* Take it out of soft reset */ status = vid_blk_read_byte(dev, GENERAL_CTL, &gen_ctrl); gen_ctrl &= ~1; status = vid_blk_write_byte(dev, GENERAL_CTL, gen_ctrl); return status; } /****************************************************************************** * C H I P Specific C O N T R O L functions * ******************************************************************************/ int cx231xx_init_ctrl_pin_status(struct cx231xx *dev) { u32 value; int status = 0; status = vid_blk_read_word(dev, PIN_CTRL, &value); value |= (~dev->board.ctl_pin_status_mask); status = vid_blk_write_word(dev, PIN_CTRL, value); return status; } int cx231xx_set_agc_analog_digital_mux_select(struct cx231xx *dev, u8 analog_or_digital) { int status = 0; /* first set the direction to output */ status = cx231xx_set_gpio_direction(dev, dev->board. agc_analog_digital_select_gpio, 1); /* 0 - demod ; 1 - Analog mode */ status = cx231xx_set_gpio_value(dev, dev->board.agc_analog_digital_select_gpio, analog_or_digital); if (status < 0) return status; return 0; } int cx231xx_enable_i2c_port_3(struct cx231xx *dev, bool is_port_3) { u8 value[4] = { 0, 0, 0, 0 }; int status = 0; bool current_is_port_3; /* * Should this code check dev->port_3_switch_enabled first * to skip unnecessary reading of the register? * If yes, the flag dev->port_3_switch_enabled must be initialized * correctly. */ status = cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, PWR_CTL_EN, value, 4); if (status < 0) return status; current_is_port_3 = value[0] & I2C_DEMOD_EN ? true : false; /* Just return, if already using the right port */ if (current_is_port_3 == is_port_3) return 0; if (is_port_3) value[0] |= I2C_DEMOD_EN; else value[0] &= ~I2C_DEMOD_EN; status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); /* remember status of the switch for usage in is_tuner */ if (status >= 0) dev->port_3_switch_enabled = is_port_3; return status; } EXPORT_SYMBOL_GPL(cx231xx_enable_i2c_port_3); void update_HH_register_after_set_DIF(struct cx231xx *dev) { /* u8 status = 0; u32 value = 0; vid_blk_write_word(dev, PIN_CTRL, 0xA0FFF82F); vid_blk_write_word(dev, DIF_MISC_CTRL, 0x0A203F11); vid_blk_write_word(dev, DIF_SRC_PHASE_INC, 0x1BEFBF06); status = vid_blk_read_word(dev, AFE_CTRL_C2HH_SRC_CTRL, &value); vid_blk_write_word(dev, AFE_CTRL_C2HH_SRC_CTRL, 0x4485D390); status = vid_blk_read_word(dev, AFE_CTRL_C2HH_SRC_CTRL, &value); */ } void cx231xx_dump_HH_reg(struct cx231xx *dev) { u32 value = 0; u16 i = 0; value = 0x45005390; vid_blk_write_word(dev, 0x104, value); for (i = 0x100; i < 0x140; i++) { vid_blk_read_word(dev, i, &value); dev_dbg(dev->dev, "reg0x%x=0x%x\n", i, value); i = i+3; } for (i = 0x300; i < 0x400; i++) { vid_blk_read_word(dev, i, &value); dev_dbg(dev->dev, "reg0x%x=0x%x\n", i, value); i = i+3; } for (i = 0x400; i < 0x440; i++) { vid_blk_read_word(dev, i, &value); dev_dbg(dev->dev, "reg0x%x=0x%x\n", i, value); i = i+3; } vid_blk_read_word(dev, AFE_CTRL_C2HH_SRC_CTRL, &value); dev_dbg(dev->dev, "AFE_CTRL_C2HH_SRC_CTRL=0x%x\n", value); vid_blk_write_word(dev, AFE_CTRL_C2HH_SRC_CTRL, 0x4485D390); vid_blk_read_word(dev, AFE_CTRL_C2HH_SRC_CTRL, &value); dev_dbg(dev->dev, "AFE_CTRL_C2HH_SRC_CTRL=0x%x\n", value); } #if 0 static void cx231xx_dump_SC_reg(struct cx231xx *dev) { u8 value[4] = { 0, 0, 0, 0 }; dev_dbg(dev->dev, "%s!\n", __func__); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, BOARD_CFG_STAT, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", BOARD_CFG_STAT, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, TS_MODE_REG, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", TS_MODE_REG, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, TS1_CFG_REG, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", TS1_CFG_REG, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, TS1_LENGTH_REG, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", TS1_LENGTH_REG, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, TS2_CFG_REG, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", TS2_CFG_REG, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, TS2_LENGTH_REG, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", TS2_LENGTH_REG, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, EP_MODE_SET, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", EP_MODE_SET, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_PWR_PTN1, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_PWR_PTN1, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_PWR_PTN2, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_PWR_PTN2, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_PWR_PTN3, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_PWR_PTN3, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_PWR_MASK0, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_PWR_MASK0, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_PWR_MASK1, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_PWR_MASK1, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_PWR_MASK2, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_PWR_MASK2, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_GAIN, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_GAIN, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_CAR_REG, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_CAR_REG, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_OT_CFG1, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_OT_CFG1, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, CIR_OT_CFG2, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", CIR_OT_CFG2, value[0], value[1], value[2], value[3]); cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, PWR_CTL_EN, value, 4); dev_dbg(dev->dev, "reg0x%x=0x%x 0x%x 0x%x 0x%x\n", PWR_CTL_EN, value[0], value[1], value[2], value[3]); } #endif void cx231xx_Setup_AFE_for_LowIF(struct cx231xx *dev) { u8 value = 0; afe_read_byte(dev, ADC_STATUS2_CH3, &value); value = (value & 0xFE)|0x01; afe_write_byte(dev, ADC_STATUS2_CH3, value); afe_read_byte(dev, ADC_STATUS2_CH3, &value); value = (value & 0xFE)|0x00; afe_write_byte(dev, ADC_STATUS2_CH3, value); /* config colibri to lo-if mode FIXME: ntf_mode = 2'b00 by default. But set 0x1 would reduce the diff IF input by half, for low-if agc defect */ afe_read_byte(dev, ADC_NTF_PRECLMP_EN_CH3, &value); value = (value & 0xFC)|0x00; afe_write_byte(dev, ADC_NTF_PRECLMP_EN_CH3, value); afe_read_byte(dev, ADC_INPUT_CH3, &value); value = (value & 0xF9)|0x02; afe_write_byte(dev, ADC_INPUT_CH3, value); afe_read_byte(dev, ADC_FB_FRCRST_CH3, &value); value = (value & 0xFB)|0x04; afe_write_byte(dev, ADC_FB_FRCRST_CH3, value); afe_read_byte(dev, ADC_DCSERVO_DEM_CH3, &value); value = (value & 0xFC)|0x03; afe_write_byte(dev, ADC_DCSERVO_DEM_CH3, value); afe_read_byte(dev, ADC_CTRL_DAC1_CH3, &value); value = (value & 0xFB)|0x04; afe_write_byte(dev, ADC_CTRL_DAC1_CH3, value); afe_read_byte(dev, ADC_CTRL_DAC23_CH3, &value); value = (value & 0xF8)|0x06; afe_write_byte(dev, ADC_CTRL_DAC23_CH3, value); afe_read_byte(dev, ADC_CTRL_DAC23_CH3, &value); value = (value & 0x8F)|0x40; afe_write_byte(dev, ADC_CTRL_DAC23_CH3, value); afe_read_byte(dev, ADC_PWRDN_CLAMP_CH3, &value); value = (value & 0xDF)|0x20; afe_write_byte(dev, ADC_PWRDN_CLAMP_CH3, value); } void cx231xx_set_Colibri_For_LowIF(struct cx231xx *dev, u32 if_freq, u8 spectral_invert, u32 mode) { u32 colibri_carrier_offset = 0; u32 func_mode = 0x01; /* Device has a DIF if this function is called */ u32 standard = 0; u8 value[4] = { 0, 0, 0, 0 }; dev_dbg(dev->dev, "Enter cx231xx_set_Colibri_For_LowIF()\n"); value[0] = (u8) 0x6F; value[1] = (u8) 0x6F; value[2] = (u8) 0x6F; value[3] = (u8) 0x6F; cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); /*Set colibri for low IF*/ cx231xx_afe_set_mode(dev, AFE_MODE_LOW_IF); /* Set C2HH for low IF operation.*/ standard = dev->norm; cx231xx_dif_configure_C2HH_for_low_IF(dev, dev->active_mode, func_mode, standard); /* Get colibri offsets.*/ colibri_carrier_offset = cx231xx_Get_Colibri_CarrierOffset(mode, standard); dev_dbg(dev->dev, "colibri_carrier_offset=%d, standard=0x%x\n", colibri_carrier_offset, standard); /* Set the band Pass filter for DIF*/ cx231xx_set_DIF_bandpass(dev, (if_freq+colibri_carrier_offset), spectral_invert, mode); } u32 cx231xx_Get_Colibri_CarrierOffset(u32 mode, u32 standerd) { u32 colibri_carrier_offset = 0; if (mode == TUNER_MODE_FM_RADIO) { colibri_carrier_offset = 1100000; } else if (standerd & (V4L2_STD_MN | V4L2_STD_NTSC_M_JP)) { colibri_carrier_offset = 4832000; /*4.83MHz */ } else if (standerd & (V4L2_STD_PAL_B | V4L2_STD_PAL_G)) { colibri_carrier_offset = 2700000; /*2.70MHz */ } else if (standerd & (V4L2_STD_PAL_D | V4L2_STD_PAL_I | V4L2_STD_SECAM)) { colibri_carrier_offset = 2100000; /*2.10MHz */ } return colibri_carrier_offset; } void cx231xx_set_DIF_bandpass(struct cx231xx *dev, u32 if_freq, u8 spectral_invert, u32 mode) { unsigned long pll_freq_word; u32 dif_misc_ctrl_value = 0; u64 pll_freq_u64 = 0; u32 i = 0; dev_dbg(dev->dev, "if_freq=%d;spectral_invert=0x%x;mode=0x%x\n", if_freq, spectral_invert, mode); if (mode == TUNER_MODE_FM_RADIO) { pll_freq_word = 0x905A1CAC; vid_blk_write_word(dev, DIF_PLL_FREQ_WORD, pll_freq_word); } else /*KSPROPERTY_TUNER_MODE_TV*/{ /* Calculate the PLL frequency word based on the adjusted if_freq*/ pll_freq_word = if_freq; pll_freq_u64 = (u64)pll_freq_word << 28L; do_div(pll_freq_u64, 50000000); pll_freq_word = (u32)pll_freq_u64; /*pll_freq_word = 0x3463497;*/ vid_blk_write_word(dev, DIF_PLL_FREQ_WORD, pll_freq_word); if (spectral_invert) { if_freq -= 400000; /* Enable Spectral Invert*/ vid_blk_read_word(dev, DIF_MISC_CTRL, &dif_misc_ctrl_value); dif_misc_ctrl_value = dif_misc_ctrl_value | 0x00200000; vid_blk_write_word(dev, DIF_MISC_CTRL, dif_misc_ctrl_value); } else { if_freq += 400000; /* Disable Spectral Invert*/ vid_blk_read_word(dev, DIF_MISC_CTRL, &dif_misc_ctrl_value); dif_misc_ctrl_value = dif_misc_ctrl_value & 0xFFDFFFFF; vid_blk_write_word(dev, DIF_MISC_CTRL, dif_misc_ctrl_value); } if_freq = (if_freq / 100000) * 100000; if (if_freq < 3000000) if_freq = 3000000; if (if_freq > 16000000) if_freq = 16000000; } dev_dbg(dev->dev, "Enter IF=%zu\n", ARRAY_SIZE(Dif_set_array)); for (i = 0; i < ARRAY_SIZE(Dif_set_array); i++) { if (Dif_set_array[i].if_freq == if_freq) { vid_blk_write_word(dev, Dif_set_array[i].register_address, Dif_set_array[i].value); } } } /****************************************************************************** * D I F - B L O C K C O N T R O L functions * ******************************************************************************/ int cx231xx_dif_configure_C2HH_for_low_IF(struct cx231xx *dev, u32 mode, u32 function_mode, u32 standard) { int status = 0; if (mode == V4L2_TUNER_RADIO) { /* C2HH */ /* lo if big signal */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 30, 31, 0x1); /* FUNC_MODE = DIF */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 23, 24, function_mode); /* IF_MODE */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 15, 22, 0xFF); /* no inv */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 9, 9, 0x1); } else if (standard != DIF_USE_BASEBAND) { if (standard & V4L2_STD_MN) { /* lo if big signal */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 30, 31, 0x1); /* FUNC_MODE = DIF */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 23, 24, function_mode); /* IF_MODE */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 15, 22, 0xb); /* no inv */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 9, 9, 0x1); /* 0x124, AUD_CHAN1_SRC = 0x3 */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AUD_IO_CTRL, 0, 31, 0x00000003); } else if ((standard == V4L2_STD_PAL_I) | (standard & V4L2_STD_PAL_D) | (standard & V4L2_STD_SECAM)) { /* C2HH setup */ /* lo if big signal */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 30, 31, 0x1); /* FUNC_MODE = DIF */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 23, 24, function_mode); /* IF_MODE */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 15, 22, 0xF); /* no inv */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 9, 9, 0x1); } else { /* default PAL BG */ /* C2HH setup */ /* lo if big signal */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 30, 31, 0x1); /* FUNC_MODE = DIF */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 23, 24, function_mode); /* IF_MODE */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 15, 22, 0xE); /* no inv */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, AFE_CTRL_C2HH_SRC_CTRL, 9, 9, 0x1); } } return status; } int cx231xx_dif_set_standard(struct cx231xx *dev, u32 standard) { int status = 0; u32 dif_misc_ctrl_value = 0; u32 func_mode = 0; dev_dbg(dev->dev, "%s: setStandard to %x\n", __func__, standard); status = vid_blk_read_word(dev, DIF_MISC_CTRL, &dif_misc_ctrl_value); if (standard != DIF_USE_BASEBAND) dev->norm = standard; switch (dev->model) { case CX231XX_BOARD_CNXT_CARRAERA: case CX231XX_BOARD_CNXT_RDE_250: case CX231XX_BOARD_CNXT_SHELBY: case CX231XX_BOARD_CNXT_RDU_250: case CX231XX_BOARD_CNXT_VIDEO_GRABBER: case CX231XX_BOARD_HAUPPAUGE_EXETER: case CX231XX_BOARD_OTG102: func_mode = 0x03; break; case CX231XX_BOARD_CNXT_RDE_253S: case CX231XX_BOARD_CNXT_RDU_253S: case CX231XX_BOARD_HAUPPAUGE_USB2_FM_PAL: case CX231XX_BOARD_HAUPPAUGE_USB2_FM_NTSC: func_mode = 0x01; break; default: func_mode = 0x01; } status = cx231xx_dif_configure_C2HH_for_low_IF(dev, dev->active_mode, func_mode, standard); if (standard == DIF_USE_BASEBAND) { /* base band */ /* There is a different SRC_PHASE_INC value for baseband vs. DIF */ status = vid_blk_write_word(dev, DIF_SRC_PHASE_INC, 0xDF7DF83); status = vid_blk_read_word(dev, DIF_MISC_CTRL, &dif_misc_ctrl_value); dif_misc_ctrl_value |= FLD_DIF_DIF_BYPASS; status = vid_blk_write_word(dev, DIF_MISC_CTRL, dif_misc_ctrl_value); } else if (standard & V4L2_STD_PAL_D) { status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL, 0, 31, 0x6503bc0c); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL1, 0, 31, 0xbd038c85); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL2, 0, 31, 0x1db4640a); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL3, 0, 31, 0x00008800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_REF, 0, 31, 0x444C1380); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_IF, 0, 31, 0xDA302600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_INT, 0, 31, 0xDA261700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_RF, 0, 31, 0xDA262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_INT_CURRENT, 0, 31, 0x26001700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_RF_CURRENT, 0, 31, 0x00002660); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VIDEO_AGC_CTRL, 0, 31, 0x72500800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VID_AUD_OVERRIDE, 0, 31, 0x27000100); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AV_SEP_CTRL, 0, 31, 0x3F3934EA); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_COMP_FLT_CTRL, 0, 31, 0x00000000); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_PHASE_INC, 0, 31, 0x1befbf06); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_GAIN_CONTROL, 0, 31, 0x000035e8); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_RPT_VARIANCE, 0, 31, 0x00000000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3a023F11; } else if (standard & V4L2_STD_PAL_I) { status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL, 0, 31, 0x6503bc0c); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL1, 0, 31, 0xbd038c85); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL2, 0, 31, 0x1db4640a); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL3, 0, 31, 0x00008800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_REF, 0, 31, 0x444C1380); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_IF, 0, 31, 0xDA302600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_INT, 0, 31, 0xDA261700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_RF, 0, 31, 0xDA262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_INT_CURRENT, 0, 31, 0x26001700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_RF_CURRENT, 0, 31, 0x00002660); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VIDEO_AGC_CTRL, 0, 31, 0x72500800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VID_AUD_OVERRIDE, 0, 31, 0x27000100); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AV_SEP_CTRL, 0, 31, 0x5F39A934); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_COMP_FLT_CTRL, 0, 31, 0x00000000); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_PHASE_INC, 0, 31, 0x1befbf06); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_GAIN_CONTROL, 0, 31, 0x000035e8); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_RPT_VARIANCE, 0, 31, 0x00000000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3a033F11; } else if (standard & V4L2_STD_PAL_M) { /* improved Low Frequency Phase Noise */ status = vid_blk_write_word(dev, DIF_PLL_CTRL, 0xFF01FF0C); status = vid_blk_write_word(dev, DIF_PLL_CTRL1, 0xbd038c85); status = vid_blk_write_word(dev, DIF_PLL_CTRL2, 0x1db4640a); status = vid_blk_write_word(dev, DIF_PLL_CTRL3, 0x00008800); status = vid_blk_write_word(dev, DIF_AGC_IF_REF, 0x444C1380); status = vid_blk_write_word(dev, DIF_AGC_IF_INT_CURRENT, 0x26001700); status = vid_blk_write_word(dev, DIF_AGC_RF_CURRENT, 0x00002660); status = vid_blk_write_word(dev, DIF_VIDEO_AGC_CTRL, 0x72500800); status = vid_blk_write_word(dev, DIF_VID_AUD_OVERRIDE, 0x27000100); status = vid_blk_write_word(dev, DIF_AV_SEP_CTRL, 0x012c405d); status = vid_blk_write_word(dev, DIF_COMP_FLT_CTRL, 0x009f50c1); status = vid_blk_write_word(dev, DIF_SRC_PHASE_INC, 0x1befbf06); status = vid_blk_write_word(dev, DIF_SRC_GAIN_CONTROL, 0x000035e8); status = vid_blk_write_word(dev, DIF_SOFT_RST_CTRL_REVB, 0x00000000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3A0A3F10; } else if (standard & (V4L2_STD_PAL_N | V4L2_STD_PAL_Nc)) { /* improved Low Frequency Phase Noise */ status = vid_blk_write_word(dev, DIF_PLL_CTRL, 0xFF01FF0C); status = vid_blk_write_word(dev, DIF_PLL_CTRL1, 0xbd038c85); status = vid_blk_write_word(dev, DIF_PLL_CTRL2, 0x1db4640a); status = vid_blk_write_word(dev, DIF_PLL_CTRL3, 0x00008800); status = vid_blk_write_word(dev, DIF_AGC_IF_REF, 0x444C1380); status = vid_blk_write_word(dev, DIF_AGC_IF_INT_CURRENT, 0x26001700); status = vid_blk_write_word(dev, DIF_AGC_RF_CURRENT, 0x00002660); status = vid_blk_write_word(dev, DIF_VIDEO_AGC_CTRL, 0x72500800); status = vid_blk_write_word(dev, DIF_VID_AUD_OVERRIDE, 0x27000100); status = vid_blk_write_word(dev, DIF_AV_SEP_CTRL, 0x012c405d); status = vid_blk_write_word(dev, DIF_COMP_FLT_CTRL, 0x009f50c1); status = vid_blk_write_word(dev, DIF_SRC_PHASE_INC, 0x1befbf06); status = vid_blk_write_word(dev, DIF_SRC_GAIN_CONTROL, 0x000035e8); status = vid_blk_write_word(dev, DIF_SOFT_RST_CTRL_REVB, 0x00000000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value = 0x3A093F10; } else if (standard & (V4L2_STD_SECAM_B | V4L2_STD_SECAM_D | V4L2_STD_SECAM_G | V4L2_STD_SECAM_K | V4L2_STD_SECAM_K1)) { status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL, 0, 31, 0x6503bc0c); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL1, 0, 31, 0xbd038c85); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL2, 0, 31, 0x1db4640a); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL3, 0, 31, 0x00008800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_REF, 0, 31, 0x888C0380); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_IF, 0, 31, 0xe0262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_INT, 0, 31, 0xc2171700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_RF, 0, 31, 0xc2262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_INT_CURRENT, 0, 31, 0x26001700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_RF_CURRENT, 0, 31, 0x00002660); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VID_AUD_OVERRIDE, 0, 31, 0x27000100); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AV_SEP_CTRL, 0, 31, 0x3F3530ec); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_COMP_FLT_CTRL, 0, 31, 0x00000000); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_PHASE_INC, 0, 31, 0x1befbf06); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_GAIN_CONTROL, 0, 31, 0x000035e8); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_RPT_VARIANCE, 0, 31, 0x00000000); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VIDEO_AGC_CTRL, 0, 31, 0xf4000000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3a023F11; } else if (standard & (V4L2_STD_SECAM_L | V4L2_STD_SECAM_LC)) { /* Is it SECAM_L1? */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL, 0, 31, 0x6503bc0c); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL1, 0, 31, 0xbd038c85); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL2, 0, 31, 0x1db4640a); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL3, 0, 31, 0x00008800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_REF, 0, 31, 0x888C0380); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_IF, 0, 31, 0xe0262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_INT, 0, 31, 0xc2171700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_RF, 0, 31, 0xc2262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_INT_CURRENT, 0, 31, 0x26001700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_RF_CURRENT, 0, 31, 0x00002660); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VID_AUD_OVERRIDE, 0, 31, 0x27000100); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AV_SEP_CTRL, 0, 31, 0x3F3530ec); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_COMP_FLT_CTRL, 0, 31, 0x00000000); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_PHASE_INC, 0, 31, 0x1befbf06); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_GAIN_CONTROL, 0, 31, 0x000035e8); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_RPT_VARIANCE, 0, 31, 0x00000000); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VIDEO_AGC_CTRL, 0, 31, 0xf2560000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3a023F11; } else if (standard & V4L2_STD_NTSC_M) { /* V4L2_STD_NTSC_M (75 IRE Setup) Or V4L2_STD_NTSC_M_JP (Japan, 0 IRE Setup) */ /* For NTSC the centre frequency of video coming out of sidewinder is around 7.1MHz or 3.6MHz depending on the spectral inversion. so for a non spectrally inverted channel the pll freq word is 0x03420c49 */ status = vid_blk_write_word(dev, DIF_PLL_CTRL, 0x6503BC0C); status = vid_blk_write_word(dev, DIF_PLL_CTRL1, 0xBD038C85); status = vid_blk_write_word(dev, DIF_PLL_CTRL2, 0x1DB4640A); status = vid_blk_write_word(dev, DIF_PLL_CTRL3, 0x00008800); status = vid_blk_write_word(dev, DIF_AGC_IF_REF, 0x444C0380); status = vid_blk_write_word(dev, DIF_AGC_IF_INT_CURRENT, 0x26001700); status = vid_blk_write_word(dev, DIF_AGC_RF_CURRENT, 0x00002660); status = vid_blk_write_word(dev, DIF_VIDEO_AGC_CTRL, 0x04000800); status = vid_blk_write_word(dev, DIF_VID_AUD_OVERRIDE, 0x27000100); status = vid_blk_write_word(dev, DIF_AV_SEP_CTRL, 0x01296e1f); status = vid_blk_write_word(dev, DIF_COMP_FLT_CTRL, 0x009f50c1); status = vid_blk_write_word(dev, DIF_SRC_PHASE_INC, 0x1befbf06); status = vid_blk_write_word(dev, DIF_SRC_GAIN_CONTROL, 0x000035e8); status = vid_blk_write_word(dev, DIF_AGC_CTRL_IF, 0xC2262600); status = vid_blk_write_word(dev, DIF_AGC_CTRL_INT, 0xC2262600); status = vid_blk_write_word(dev, DIF_AGC_CTRL_RF, 0xC2262600); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3a003F10; } else { /* default PAL BG */ status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL, 0, 31, 0x6503bc0c); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL1, 0, 31, 0xbd038c85); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL2, 0, 31, 0x1db4640a); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_PLL_CTRL3, 0, 31, 0x00008800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_REF, 0, 31, 0x444C1380); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_IF, 0, 31, 0xDA302600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_INT, 0, 31, 0xDA261700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_CTRL_RF, 0, 31, 0xDA262600); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_IF_INT_CURRENT, 0, 31, 0x26001700); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AGC_RF_CURRENT, 0, 31, 0x00002660); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VIDEO_AGC_CTRL, 0, 31, 0x72500800); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_VID_AUD_OVERRIDE, 0, 31, 0x27000100); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_AV_SEP_CTRL, 0, 31, 0x3F3530EC); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_COMP_FLT_CTRL, 0, 31, 0x00A653A8); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_PHASE_INC, 0, 31, 0x1befbf06); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_SRC_GAIN_CONTROL, 0, 31, 0x000035e8); status = cx231xx_reg_mask_write(dev, VID_BLK_I2C_ADDRESS, 32, DIF_RPT_VARIANCE, 0, 31, 0x00000000); /* Save the Spec Inversion value */ dif_misc_ctrl_value &= FLD_DIF_SPEC_INV; dif_misc_ctrl_value |= 0x3a013F11; } /* The AGC values should be the same for all standards, AUD_SRC_SEL[19] should always be disabled */ dif_misc_ctrl_value &= ~FLD_DIF_AUD_SRC_SEL; /* It is still possible to get Set Standard calls even when we are in FM mode. This is done to override the value for FM. */ if (dev->active_mode == V4L2_TUNER_RADIO) dif_misc_ctrl_value = 0x7a080000; /* Write the calculated value for misc ontrol register */ status = vid_blk_write_word(dev, DIF_MISC_CTRL, dif_misc_ctrl_value); return status; } int cx231xx_tuner_pre_channel_change(struct cx231xx *dev) { int status = 0; u32 dwval; /* Set the RF and IF k_agc values to 3 */ status = vid_blk_read_word(dev, DIF_AGC_IF_REF, &dwval); dwval &= ~(FLD_DIF_K_AGC_RF | FLD_DIF_K_AGC_IF); dwval |= 0x33000000; status = vid_blk_write_word(dev, DIF_AGC_IF_REF, dwval); return status; } int cx231xx_tuner_post_channel_change(struct cx231xx *dev) { int status = 0; u32 dwval; dev_dbg(dev->dev, "%s: dev->tuner_type =0%d\n", __func__, dev->tuner_type); /* Set the RF and IF k_agc values to 4 for PAL/NTSC and 8 for * SECAM L/B/D standards */ status = vid_blk_read_word(dev, DIF_AGC_IF_REF, &dwval); dwval &= ~(FLD_DIF_K_AGC_RF | FLD_DIF_K_AGC_IF); if (dev->norm & (V4L2_STD_SECAM_L | V4L2_STD_SECAM_B | V4L2_STD_SECAM_D)) { if (dev->tuner_type == TUNER_NXP_TDA18271) { dwval &= ~FLD_DIF_IF_REF; dwval |= 0x88000300; } else dwval |= 0x88000000; } else { if (dev->tuner_type == TUNER_NXP_TDA18271) { dwval &= ~FLD_DIF_IF_REF; dwval |= 0xCC000300; } else dwval |= 0x44000000; } status = vid_blk_write_word(dev, DIF_AGC_IF_REF, dwval); return status == sizeof(dwval) ? 0 : -EIO; } /****************************************************************************** * I 2 S - B L O C K C O N T R O L functions * ******************************************************************************/ int cx231xx_i2s_blk_initialize(struct cx231xx *dev) { int status = 0; u32 value; status = cx231xx_read_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL1, 1, &value, 1); /* enables clock to delta-sigma and decimation filter */ value |= 0x80; status = cx231xx_write_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL1, 1, value, 1); /* power up all channel */ status = cx231xx_write_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL2, 1, 0x00, 1); return status; } int cx231xx_i2s_blk_update_power_control(struct cx231xx *dev, enum AV_MODE avmode) { int status = 0; u32 value = 0; if (avmode != POLARIS_AVMODE_ENXTERNAL_AV) { status = cx231xx_read_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL2, 1, &value, 1); value |= 0xfe; status = cx231xx_write_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL2, 1, value, 1); } else { status = cx231xx_write_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL2, 1, 0x00, 1); } return status; } /* set i2s_blk for audio input types */ int cx231xx_i2s_blk_set_audio_input(struct cx231xx *dev, u8 audio_input) { int status = 0; switch (audio_input) { case CX231XX_AMUX_LINE_IN: status = cx231xx_write_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL2, 1, 0x00, 1); status = cx231xx_write_i2c_data(dev, I2S_BLK_DEVICE_ADDRESS, CH_PWR_CTRL1, 1, 0x80, 1); break; case CX231XX_AMUX_VIDEO: default: break; } dev->ctl_ainput = audio_input; return status; } /****************************************************************************** * P O W E R C O N T R O L functions * ******************************************************************************/ int cx231xx_set_power_mode(struct cx231xx *dev, enum AV_MODE mode) { u8 value[4] = { 0, 0, 0, 0 }; u32 tmp = 0; int status = 0; if (dev->power_mode != mode) dev->power_mode = mode; else { dev_dbg(dev->dev, "%s: mode = %d, No Change req.\n", __func__, mode); return 0; } status = cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, PWR_CTL_EN, value, 4); if (status < 0) return status; tmp = le32_to_cpu(*((__le32 *) value)); switch (mode) { case POLARIS_AVMODE_ENXTERNAL_AV: tmp &= (~PWR_MODE_MASK); tmp |= PWR_AV_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); tmp |= PWR_ISO_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); tmp |= POLARIS_AVMODE_ENXTERNAL_AV; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); /* reset state of xceive tuner */ dev->xc_fw_load_done = 0; break; case POLARIS_AVMODE_ANALOGT_TV: tmp |= PWR_DEMOD_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); if (!(tmp & PWR_TUNER_EN)) { tmp |= (PWR_TUNER_EN); value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (!(tmp & PWR_AV_EN)) { tmp |= PWR_AV_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (!(tmp & PWR_ISO_EN)) { tmp |= PWR_ISO_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (!(tmp & POLARIS_AVMODE_ANALOGT_TV)) { tmp |= POLARIS_AVMODE_ANALOGT_TV; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (dev->board.tuner_type != TUNER_ABSENT) { /* reset the Tuner */ if (dev->board.tuner_gpio) cx231xx_gpio_set(dev, dev->board.tuner_gpio); if (dev->cx231xx_reset_analog_tuner) dev->cx231xx_reset_analog_tuner(dev); } break; case POLARIS_AVMODE_DIGITAL: if (!(tmp & PWR_TUNER_EN)) { tmp |= (PWR_TUNER_EN); value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (!(tmp & PWR_AV_EN)) { tmp |= PWR_AV_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (!(tmp & PWR_ISO_EN)) { tmp |= PWR_ISO_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } tmp &= (~PWR_AV_MODE); tmp |= POLARIS_AVMODE_DIGITAL; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); if (!(tmp & PWR_DEMOD_EN)) { tmp |= PWR_DEMOD_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } if (dev->board.tuner_type != TUNER_ABSENT) { /* reset the Tuner */ if (dev->board.tuner_gpio) cx231xx_gpio_set(dev, dev->board.tuner_gpio); if (dev->cx231xx_reset_analog_tuner) dev->cx231xx_reset_analog_tuner(dev); } break; default: break; } msleep(PWR_SLEEP_INTERVAL); /* For power saving, only enable Pwr_resetout_n when digital TV is selected. */ if (mode == POLARIS_AVMODE_DIGITAL) { tmp |= PWR_RESETOUT_EN; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); msleep(PWR_SLEEP_INTERVAL); } /* update power control for afe */ status = cx231xx_afe_update_power_control(dev, mode); /* update power control for i2s_blk */ status = cx231xx_i2s_blk_update_power_control(dev, mode); status = cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, PWR_CTL_EN, value, 4); return status; } int cx231xx_power_suspend(struct cx231xx *dev) { u8 value[4] = { 0, 0, 0, 0 }; u32 tmp = 0; int status = 0; status = cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, PWR_CTL_EN, value, 4); if (status > 0) return status; tmp = le32_to_cpu(*((__le32 *) value)); tmp &= (~PWR_MODE_MASK); value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, PWR_CTL_EN, value, 4); return status; } /****************************************************************************** * S T R E A M C O N T R O L functions * ******************************************************************************/ int cx231xx_start_stream(struct cx231xx *dev, u32 ep_mask) { u8 value[4] = { 0x0, 0x0, 0x0, 0x0 }; u32 tmp = 0; int status = 0; dev_dbg(dev->dev, "%s: ep_mask = %x\n", __func__, ep_mask); status = cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, EP_MODE_SET, value, 4); if (status < 0) return status; tmp = le32_to_cpu(*((__le32 *) value)); tmp |= ep_mask; value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, EP_MODE_SET, value, 4); return status; } int cx231xx_stop_stream(struct cx231xx *dev, u32 ep_mask) { u8 value[4] = { 0x0, 0x0, 0x0, 0x0 }; u32 tmp = 0; int status = 0; dev_dbg(dev->dev, "%s: ep_mask = %x\n", __func__, ep_mask); status = cx231xx_read_ctrl_reg(dev, VRT_GET_REGISTER, EP_MODE_SET, value, 4); if (status < 0) return status; tmp = le32_to_cpu(*((__le32 *) value)); tmp &= (~ep_mask); value[0] = (u8) tmp; value[1] = (u8) (tmp >> 8); value[2] = (u8) (tmp >> 16); value[3] = (u8) (tmp >> 24); status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, EP_MODE_SET, value, 4); return status; } int cx231xx_initialize_stream_xfer(struct cx231xx *dev, u32 media_type) { int status = 0; u32 value = 0; u8 val[4] = { 0, 0, 0, 0 }; if (dev->udev->speed == USB_SPEED_HIGH) { switch (media_type) { case Audio: dev_dbg(dev->dev, "%s: Audio enter HANC\n", __func__); status = cx231xx_mode_register(dev, TS_MODE_REG, 0x9300); break; case Vbi: dev_dbg(dev->dev, "%s: set vanc registers\n", __func__); status = cx231xx_mode_register(dev, TS_MODE_REG, 0x300); break; case Sliced_cc: dev_dbg(dev->dev, "%s: set hanc registers\n", __func__); status = cx231xx_mode_register(dev, TS_MODE_REG, 0x1300); break; case Raw_Video: dev_dbg(dev->dev, "%s: set video registers\n", __func__); status = cx231xx_mode_register(dev, TS_MODE_REG, 0x100); break; case TS1_serial_mode: dev_dbg(dev->dev, "%s: set ts1 registers", __func__); if (dev->board.has_417) { dev_dbg(dev->dev, "%s: MPEG\n", __func__); value &= 0xFFFFFFFC; value |= 0x3; status = cx231xx_mode_register(dev, TS_MODE_REG, value); val[0] = 0x04; val[1] = 0xA3; val[2] = 0x3B; val[3] = 0x00; status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, TS1_CFG_REG, val, 4); val[0] = 0x00; val[1] = 0x08; val[2] = 0x00; val[3] = 0x08; status = cx231xx_write_ctrl_reg(dev, VRT_SET_REGISTER, TS1_LENGTH_REG, val, 4); } else { dev_dbg(dev->dev, "%s: BDA\n", __func__); status = cx231xx_mode_register(dev, TS_MODE_REG, 0x101); status = cx231xx_mode_register(dev, TS1_CFG_REG, 0x010); } break; case TS1_parallel_mode: dev_dbg(dev->dev, "%s: set ts1 parallel mode registers\n", __func__); status = cx231xx_mode_register(dev, TS_MODE_REG, 0x100); status = cx231xx_mode_register(dev, TS1_CFG_REG, 0x400); break; } } else { status = cx231xx_mode_register(dev, TS_MODE_REG, 0x101); } return status; } int cx231xx_capture_start(struct cx231xx *dev, int start, u8 media_type) { int rc = -1; u32 ep_mask = -1; struct pcb_config *pcb_config; /* get EP for media type */ pcb_config = (struct pcb_config *)&dev->current_pcb_config; if (pcb_config->config_num) { switch (media_type) { case Raw_Video: ep_mask = ENABLE_EP4; /* ep4 [00:1000] */ break; case Audio: ep_mask = ENABLE_EP3; /* ep3 [00:0100] */ break; case Vbi: ep_mask = ENABLE_EP5; /* ep5 [01:0000] */ break; case Sliced_cc: ep_mask = ENABLE_EP6; /* ep6 [10:0000] */ break; case TS1_serial_mode: case TS1_parallel_mode: ep_mask = ENABLE_EP1; /* ep1 [00:0001] */ break; case TS2: ep_mask = ENABLE_EP2; /* ep2 [00:0010] */ break; } } if (start) { rc = cx231xx_initialize_stream_xfer(dev, media_type); if (rc < 0) return rc; /* enable video capture */ if (ep_mask > 0) rc = cx231xx_start_stream(dev, ep_mask); } else { /* disable video capture */ if (ep_mask > 0) rc = cx231xx_stop_stream(dev, ep_mask); } return rc; } EXPORT_SYMBOL_GPL(cx231xx_capture_start); /***************************************************************************** * G P I O B I T control functions * ******************************************************************************/ static int cx231xx_set_gpio_bit(struct cx231xx *dev, u32 gpio_bit, u32 gpio_val) { int status = 0; gpio_val = (__force u32)cpu_to_le32(gpio_val); status = cx231xx_send_gpio_cmd(dev, gpio_bit, (u8 *)&gpio_val, 4, 0, 0); return status; } static int cx231xx_get_gpio_bit(struct cx231xx *dev, u32 gpio_bit, u32 *gpio_val) { __le32 tmp; int status = 0; status = cx231xx_send_gpio_cmd(dev, gpio_bit, (u8 *)&tmp, 4, 0, 1); *gpio_val = le32_to_cpu(tmp); return status; } /* * cx231xx_set_gpio_direction * Sets the direction of the GPIO pin to input or output * * Parameters : * pin_number : The GPIO Pin number to program the direction for * from 0 to 31 * pin_value : The Direction of the GPIO Pin under reference. * 0 = Input direction * 1 = Output direction */ int cx231xx_set_gpio_direction(struct cx231xx *dev, int pin_number, int pin_value) { int status = 0; u32 value = 0; /* Check for valid pin_number - if 32 , bail out */ if (pin_number >= 32) return -EINVAL; /* input */ if (pin_value == 0) value = dev->gpio_dir & (~(1 << pin_number)); /* clear */ else value = dev->gpio_dir | (1 << pin_number); status = cx231xx_set_gpio_bit(dev, value, dev->gpio_val); /* cache the value for future */ dev->gpio_dir = value; return status; } /* * cx231xx_set_gpio_value * Sets the value of the GPIO pin to Logic high or low. The Pin under * reference should ALREADY BE SET IN OUTPUT MODE !!!!!!!!! * * Parameters : * pin_number : The GPIO Pin number to program the direction for * pin_value : The value of the GPIO Pin under reference. * 0 = set it to 0 * 1 = set it to 1 */ int cx231xx_set_gpio_value(struct cx231xx *dev, int pin_number, int pin_value) { int status = 0; u32 value = 0; /* Check for valid pin_number - if 0xFF , bail out */ if (pin_number >= 32) return -EINVAL; /* first do a sanity check - if the Pin is not output, make it output */ if ((dev->gpio_dir & (1 << pin_number)) == 0x00) { /* It was in input mode */ value = dev->gpio_dir | (1 << pin_number); dev->gpio_dir = value; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); value = 0; } if (pin_value == 0) value = dev->gpio_val & (~(1 << pin_number)); else value = dev->gpio_val | (1 << pin_number); /* store the value */ dev->gpio_val = value; /* toggle bit0 of GP_IO */ status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); return status; } /***************************************************************************** * G P I O I2C related functions * ******************************************************************************/ int cx231xx_gpio_i2c_start(struct cx231xx *dev) { int status = 0; /* set SCL to output 1 ; set SDA to output 1 */ dev->gpio_dir |= 1 << dev->board.tuner_scl_gpio; dev->gpio_dir |= 1 << dev->board.tuner_sda_gpio; dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; dev->gpio_val |= 1 << dev->board.tuner_sda_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); if (status < 0) return -EINVAL; /* set SCL to output 1; set SDA to output 0 */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); if (status < 0) return -EINVAL; /* set SCL to output 0; set SDA to output 0 */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); if (status < 0) return -EINVAL; return status; } int cx231xx_gpio_i2c_end(struct cx231xx *dev) { int status = 0; /* set SCL to output 0; set SDA to output 0 */ dev->gpio_dir |= 1 << dev->board.tuner_scl_gpio; dev->gpio_dir |= 1 << dev->board.tuner_sda_gpio; dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); if (status < 0) return -EINVAL; /* set SCL to output 1; set SDA to output 0 */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); if (status < 0) return -EINVAL; /* set SCL to input ,release SCL cable control set SDA to input ,release SDA cable control */ dev->gpio_dir &= ~(1 << dev->board.tuner_scl_gpio); dev->gpio_dir &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); if (status < 0) return -EINVAL; return status; } int cx231xx_gpio_i2c_write_byte(struct cx231xx *dev, u8 data) { int status = 0; u8 i; /* set SCL to output ; set SDA to output */ dev->gpio_dir |= 1 << dev->board.tuner_scl_gpio; dev->gpio_dir |= 1 << dev->board.tuner_sda_gpio; for (i = 0; i < 8; i++) { if (((data << i) & 0x80) == 0) { /* set SCL to output 0; set SDA to output 0 */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL to output 1; set SDA to output 0 */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL to output 0; set SDA to output 0 */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); } else { /* set SCL to output 0; set SDA to output 1 */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); dev->gpio_val |= 1 << dev->board.tuner_sda_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL to output 1; set SDA to output 1 */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL to output 0; set SDA to output 1 */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); } } return status; } int cx231xx_gpio_i2c_read_byte(struct cx231xx *dev, u8 *buf) { u8 value = 0; int status = 0; u32 gpio_logic_value = 0; u8 i; /* read byte */ for (i = 0; i < 8; i++) { /* send write I2c addr */ /* set SCL to output 0; set SDA to input */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL to output 1; set SDA to input */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* get SDA data bit */ gpio_logic_value = dev->gpio_val; status = cx231xx_get_gpio_bit(dev, dev->gpio_dir, &dev->gpio_val); if ((dev->gpio_val & (1 << dev->board.tuner_sda_gpio)) != 0) value |= (1 << (8 - i - 1)); dev->gpio_val = gpio_logic_value; } /* set SCL to output 0,finish the read latest SCL signal. !!!set SDA to input, never to modify SDA direction at the same times */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* store the value */ *buf = value & 0xff; return status; } int cx231xx_gpio_i2c_read_ack(struct cx231xx *dev) { int status = 0; u32 gpio_logic_value = 0; int nCnt = 10; int nInit = nCnt; /* clock stretch; set SCL to input; set SDA to input; get SCL value till SCL = 1 */ dev->gpio_dir &= ~(1 << dev->board.tuner_sda_gpio); dev->gpio_dir &= ~(1 << dev->board.tuner_scl_gpio); gpio_logic_value = dev->gpio_val; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); do { msleep(2); status = cx231xx_get_gpio_bit(dev, dev->gpio_dir, &dev->gpio_val); nCnt--; } while (((dev->gpio_val & (1 << dev->board.tuner_scl_gpio)) == 0) && (nCnt > 0)); if (nCnt == 0) dev_dbg(dev->dev, "No ACK after %d msec -GPIO I2C failed!", nInit * 10); /* * readAck * through clock stretch, slave has given a SCL signal, * so the SDA data can be directly read. */ status = cx231xx_get_gpio_bit(dev, dev->gpio_dir, &dev->gpio_val); if ((dev->gpio_val & 1 << dev->board.tuner_sda_gpio) == 0) { dev->gpio_val = gpio_logic_value; dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); status = 0; } else { dev->gpio_val = gpio_logic_value; dev->gpio_val |= (1 << dev->board.tuner_sda_gpio); } /* read SDA end, set the SCL to output 0, after this operation, SDA direction can be changed. */ dev->gpio_val = gpio_logic_value; dev->gpio_dir |= (1 << dev->board.tuner_scl_gpio); dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); return status; } int cx231xx_gpio_i2c_write_ack(struct cx231xx *dev) { int status = 0; /* set SDA to output */ dev->gpio_dir |= 1 << dev->board.tuner_sda_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL = 0 (output); set SDA = 0 (output) */ dev->gpio_val &= ~(1 << dev->board.tuner_sda_gpio); dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL = 1 (output); set SDA = 0 (output) */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SCL = 0 (output); set SDA = 0 (output) */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set SDA to input,and then the slave will read data from SDA. */ dev->gpio_dir &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); return status; } int cx231xx_gpio_i2c_write_nak(struct cx231xx *dev) { int status = 0; /* set scl to output ; set sda to input */ dev->gpio_dir |= 1 << dev->board.tuner_scl_gpio; dev->gpio_dir &= ~(1 << dev->board.tuner_sda_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set scl to output 0; set sda to input */ dev->gpio_val &= ~(1 << dev->board.tuner_scl_gpio); status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); /* set scl to output 1; set sda to input */ dev->gpio_val |= 1 << dev->board.tuner_scl_gpio; status = cx231xx_set_gpio_bit(dev, dev->gpio_dir, dev->gpio_val); return status; } /***************************************************************************** * G P I O I2C related functions * ******************************************************************************/ /* cx231xx_gpio_i2c_read * Function to read data from gpio based I2C interface */ int cx231xx_gpio_i2c_read(struct cx231xx *dev, u8 dev_addr, u8 *buf, u8 len) { int status = 0; int i = 0; /* get the lock */ mutex_lock(&dev->gpio_i2c_lock); /* start */ status = cx231xx_gpio_i2c_start(dev); /* write dev_addr */ status = cx231xx_gpio_i2c_write_byte(dev, (dev_addr << 1) + 1); /* readAck */ status = cx231xx_gpio_i2c_read_ack(dev); /* read data */ for (i = 0; i < len; i++) { /* read data */ buf[i] = 0; status = cx231xx_gpio_i2c_read_byte(dev, &buf[i]); if ((i + 1) != len) { /* only do write ack if we more length */ status = cx231xx_gpio_i2c_write_ack(dev); } } /* write NAK - inform reads are complete */ status = cx231xx_gpio_i2c_write_nak(dev); /* write end */ status = cx231xx_gpio_i2c_end(dev); /* release the lock */ mutex_unlock(&dev->gpio_i2c_lock); return status; } /* cx231xx_gpio_i2c_write * Function to write data to gpio based I2C interface */ int cx231xx_gpio_i2c_write(struct cx231xx *dev, u8 dev_addr, u8 *buf, u8 len) { int i = 0; /* get the lock */ mutex_lock(&dev->gpio_i2c_lock); /* start */ cx231xx_gpio_i2c_start(dev); /* write dev_addr */ cx231xx_gpio_i2c_write_byte(dev, dev_addr << 1); /* read Ack */ cx231xx_gpio_i2c_read_ack(dev); for (i = 0; i < len; i++) { /* Write data */ cx231xx_gpio_i2c_write_byte(dev, buf[i]); /* read Ack */ cx231xx_gpio_i2c_read_ack(dev); } /* write End */ cx231xx_gpio_i2c_end(dev); /* release the lock */ mutex_unlock(&dev->gpio_i2c_lock); return 0; }